Domain-General Brain Regions Do Not Track Linguistic Input As Closely As Language-Selective Regions

Overview

Journal J Neurosci

Specialty Neurology

Date 2017 Sep 6

PMID 28871034

Citations 41

Authors

Idan A Blank

Evelina Fedorenko

Affiliations

Soon will be listed here.

Abstract

Language comprehension engages a cortical network of left frontal and temporal regions. Activity in this network is language-selective, showing virtually no modulation by nonlinguistic tasks. In addition, language comprehension engages a second network consisting of bilateral frontal, parietal, cingulate, and insular regions. Activity in this "multiple demand" (MD) network scales with comprehension difficulty, but also with cognitive effort across a wide range of nonlinguistic tasks in a domain-general fashion. Given the functional dissociation between the language and MD networks, their respective contributions to comprehension are likely distinct, yet such differences remain elusive. Prior neuroimaging studies have suggested that activity in each network covaries with some linguistic features that, behaviorally, influence on-line processing and comprehension. This sensitivity of the language and MD networks to local input characteristics has often been interpreted, implicitly or explicitly, as evidence that both networks track linguistic input closely, and in a manner consistent across individuals. Here, we used fMRI to directly test this assumption by comparing the BOLD signal time courses in each network across different people ( = 45, men and women) listening to the same story. Language network activity showed fewer individual differences, indicative of closer input tracking, whereas MD network activity was more idiosyncratic and, moreover, showed lower reliability within an individual across repetitions of a story. These findings constrain cognitive models of language comprehension by suggesting a novel distinction between the processes implemented in the language and MD networks. Language comprehension recruits both language-specific mechanisms and domain-general mechanisms that are engaged in many cognitive processes. In the human cortex, language-selective mechanisms are implemented in the left-lateralized "core language network", whereas domain-general mechanisms are implemented in the bilateral "multiple demand" (MD) network. Here, we report the first direct comparison of the respective contributions of these networks to naturalistic story comprehension. Using a novel combination of neuroimaging approaches we find that MD regions track stories less closely than language regions. This finding constrains the possible contributions of the MD network to comprehension, contrasts with accounts positing that this network has continuous access to linguistic input, and suggests a new typology of comprehension processes based on their extent of input tracking.

Citing Articles

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Chiou R, Duncan J, Jefferies E, Lambon Ralph M J Neurosci. 2024; 45(6).

PMID: 39663116 PMC: 11800757. DOI: 10.1523/JNEUROSCI.0233-24.2024.

The language network ages well: Preserved selectivity, lateralization, and within-network functional synchronization in older brains.

Billot A, Jhingan N, Varkanitsa M, Blank I, Ryskin R, Kiran S bioRxiv. 2024; .

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Linguistic inputs must be syntactically parsable to fully engage the language network.

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Continuous Theta-Burst Stimulation on the Left Posterior Inferior Frontal Gyrus Perturbs Complex Syntactic Processing Stability in Mandarin Chinese.

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The Language Network Reliably "Tracks" Naturalistic Meaningful Nonverbal Stimuli.

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